De novo deleterious genetic variations target a biological network centered on Aß peptide in early-onset Alzheimer disease.

We hypothesized that de novo variants (DNV) might participate in the genetic determinism of sporadic early-onset Alzheimer disease (EOAD, onset before 65 years). We investigated 14 sporadic EOAD trios first by array-comparative genomic hybridization. Two patients carried a de novo copy number variation (CNV). We then performed whole-exome sequencing in the 12 remaining trios and identified 12 non-synonymous DNVs in six patients. The two de novo CNVs (an amyloid precursor protein (APP) duplication and a BACE2 intronic deletion) and 3/12 non-synonymous DNVs (in PSEN1, VPS35 and MARK4) targeted genes from a biological network centered on the Amyloid beta (Aß) peptide. We showed that this a priori-defined genetic network was significantly enriched in amino acid-altering DNV, compared with the rest of the exome. The causality of the APP de novo duplication (which is the first reported one) was obvious. In addition, we provided evidence of the functional impact of the following three non-synonymous DNVs targeting this network: the novel PSEN1 variant resulted in exon 9 skipping in patient's RNA, leading to a pathogenic missense at exons 8-10 junction; the VPS35 missense variant led to partial loss of retromer function, which may impact neuronal APP trafficking and Aß secretion; and the MARK4 multiple nucleotide variant resulted into increased Tau phosphorylation, which may trigger enhanced Aß-induced toxicity. Despite the difficulty to recruit Alzheimer disease (AD) trios owing to age structures of the pedigrees and the genetic heterogeneity of the disease, this strategy allowed us to highlight the role of de novo pathogenic events, the putative involvement of new genes in AD genetics and the key role of Aß network alteration in AD.

Endosome protein sorting: motifs and machinery.

The steady-state localisation of membrane proteins in the endocytic system is the result of many sorting events that occur at various points throughout the endosomal pathway. A protein that has been endocytosed from the plasma membrane or sorted at the trans-Golgi network (TGN) and transported to an endosome will ultimately be delivered to one of three destinations: the plasma membrane, the TGN or the lysosome. Where a membrane protein is trafficked to depends on the interactions between sorting motifs present in the membrane protein and the machinery that can decode these motifs. Much of the protein machinery that recognises sorting motifs is conserved from yeast to man, and in this review I will discuss this machinery and the motifs that govern endosomal protein sorting.